aosp12/external/ethtool/natsemi.c

988 lines
34 KiB
C

/* Copyright 2001 Sun Microsystems (thockin@sun.com) */
#include <stdio.h>
#include "internal.h"
#define PCI_VENDOR_NATSEMI 0x100b
#define PCI_DEVICE_DP83815 0x0020
#define NATSEMI_MAGIC (PCI_VENDOR_NATSEMI | \
(PCI_DEVICE_DP83815<<16))
/* register indices in the ethtool_regs->data */
#define REG_CR 0
#define BIT_CR_TXE (1<<0)
#define BIT_CR_RXE (1<<2)
#define BIT_CR_RST (1<<8)
#define REG_CFG 1
#define BIT_CFG_BEM (1<<0)
#define BIT_CFG_BROM_DIS (1<<2)
#define BIT_CFG_PHY_DIS (1<<9)
#define BIT_CFG_PHY_RST (1<<10)
#define BIT_CFG_EXT_PHY (1<<12)
#define BIT_CFG_ANEG_EN (1<<13)
#define BIT_CFG_ANEG_100 (1<<14)
#define BIT_CFG_ANEG_FDUP (1<<15)
#define BIT_CFG_PINT_ACEN (1<<17)
#define BIT_CFG_PHY_CFG (0x3f<<18)
#define BIT_CFG_ANEG_DN (1<<27)
#define BIT_CFG_POL (1<<28)
#define BIT_CFG_FDUP (1<<29)
#define BIT_CFG_SPEED100 (1<<30)
#define BIT_CFG_LNKSTS (1<<31)
#define REG_MEAR 2
#define REG_PTSCR 3
#define BIT_PTSCR_EEBIST_FAIL (1<<0)
#define BIT_PTSCR_EELOAD_EN (1<<2)
#define BIT_PTSCR_RBIST_RXFFAIL (1<<3)
#define BIT_PTSCR_RBIST_TXFAIL (1<<4)
#define BIT_PTSCR_RBIST_RXFAIL (1<<5)
#define REG_ISR 4
#define REG_IMR 5
#define BIT_INTR_RXOK (1<<0)
#define NAME_INTR_RXOK "Rx Complete"
#define BIT_INTR_RXDESC (1<<1)
#define NAME_INTR_RXDESC "Rx Descriptor"
#define BIT_INTR_RXERR (1<<2)
#define NAME_INTR_RXERR "Rx Packet Error"
#define BIT_INTR_RXEARLY (1<<3)
#define NAME_INTR_RXEARLY "Rx Early Threshold"
#define BIT_INTR_RXIDLE (1<<4)
#define NAME_INTR_RXIDLE "Rx Idle"
#define BIT_INTR_RXORN (1<<5)
#define NAME_INTR_RXORN "Rx Overrun"
#define BIT_INTR_TXOK (1<<6)
#define NAME_INTR_TXOK "Tx Packet OK"
#define BIT_INTR_TXDESC (1<<7)
#define NAME_INTR_TXDESC "Tx Descriptor"
#define BIT_INTR_TXERR (1<<8)
#define NAME_INTR_TXERR "Tx Packet Error"
#define BIT_INTR_TXIDLE (1<<9)
#define NAME_INTR_TXIDLE "Tx Idle"
#define BIT_INTR_TXURN (1<<10)
#define NAME_INTR_TXURN "Tx Underrun"
#define BIT_INTR_MIB (1<<11)
#define NAME_INTR_MIB "MIB Service"
#define BIT_INTR_SWI (1<<12)
#define NAME_INTR_SWI "Software"
#define BIT_INTR_PME (1<<13)
#define NAME_INTR_PME "Power Management Event"
#define BIT_INTR_PHY (1<<14)
#define NAME_INTR_PHY "Phy"
#define BIT_INTR_HIBERR (1<<15)
#define NAME_INTR_HIBERR "High Bits Error"
#define BIT_INTR_RXSOVR (1<<16)
#define NAME_INTR_RXSOVR "Rx Status FIFO Overrun"
#define BIT_INTR_RTABT (1<<20)
#define NAME_INTR_RTABT "Received Target Abort"
#define BIT_INTR_RMABT (1<<20)
#define NAME_INTR_RMABT "Received Master Abort"
#define BIT_INTR_SSERR (1<<20)
#define NAME_INTR_SSERR "Signaled System Error"
#define BIT_INTR_DPERR (1<<20)
#define NAME_INTR_DPERR "Detected Parity Error"
#define BIT_INTR_RXRCMP (1<<20)
#define NAME_INTR_RXRCMP "Rx Reset Complete"
#define BIT_INTR_TXRCMP (1<<20)
#define NAME_INTR_TXRCMP "Tx Reset Complete"
#define REG_IER 6
#define BIT_IER_IE (1<<0)
#define REG_TXDP 8
#define REG_TXCFG 9
#define BIT_TXCFG_DRTH (0x3f<<0)
#define BIT_TXCFG_FLTH (0x3f<<8)
#define BIT_TXCFG_MXDMA (0x7<<20)
#define BIT_TXCFG_ATP (1<<28)
#define BIT_TXCFG_MLB (1<<29)
#define BIT_TXCFG_HBI (1<<30)
#define BIT_TXCFG_CSI (1<<31)
#define REG_RXDP 12
#define REG_RXCFG 13
#define BIT_RXCFG_DRTH (0x1f<<1)
#define BIT_RXCFG_MXDMA (0x7<<20)
#define BIT_RXCFG_ALP (1<<27)
#define BIT_RXCFG_ATX (1<<28)
#define BIT_RXCFG_ARP (1<<30)
#define BIT_RXCFG_AEP (1<<31)
#define REG_CCSR 15
#define BIT_CCSR_CLKRUN_EN (1<<0)
#define BIT_CCSR_PMEEN (1<<8)
#define BIT_CCSR_PMESTS (1<<15)
#define REG_WCSR 16
#define BIT_WCSR_WKPHY (1<<0)
#define BIT_WCSR_WKUCP (1<<1)
#define BIT_WCSR_WKMCP (1<<2)
#define BIT_WCSR_WKBCP (1<<3)
#define BIT_WCSR_WKARP (1<<4)
#define BIT_WCSR_WKPAT0 (1<<5)
#define BIT_WCSR_WKPAT1 (1<<6)
#define BIT_WCSR_WKPAT2 (1<<7)
#define BIT_WCSR_WKPAT3 (1<<8)
#define BIT_WCSR_WKMAG (1<<9)
#define BIT_WCSR_MPSOE (1<<10)
#define BIT_WCSR_SOHACK (1<<20)
#define BIT_WCSR_PHYINT (1<<22)
#define BIT_WCSR_UCASTR (1<<23)
#define BIT_WCSR_MCASTR (1<<24)
#define BIT_WCSR_BCASTR (1<<25)
#define BIT_WCSR_ARPR (1<<26)
#define BIT_WCSR_PATM0 (1<<27)
#define BIT_WCSR_PATM1 (1<<28)
#define BIT_WCSR_PATM2 (1<<29)
#define BIT_WCSR_PATM3 (1<<30)
#define BIT_WCSR_MPR (1<<31)
#define REG_PCR 17
#define BIT_PCR_PAUSE_CNT (0xffff<<0)
#define BIT_PCR_PSNEG (1<<21)
#define BIT_PCR_PS_RCVD (1<<22)
#define BIT_PCR_PS_DA (1<<29)
#define BIT_PCR_PSMCAST (1<<30)
#define BIT_PCR_PSEN (1<<31)
#define REG_RFCR 18
#define BIT_RFCR_UHEN (1<<20)
#define BIT_RFCR_MHEN (1<<21)
#define BIT_RFCR_AARP (1<<22)
#define BIT_RFCR_APAT0 (1<<23)
#define BIT_RFCR_APAT1 (1<<24)
#define BIT_RFCR_APAT2 (1<<25)
#define BIT_RFCR_APAT3 (1<<26)
#define BIT_RFCR_APM (1<<27)
#define BIT_RFCR_AAU (1<<28)
#define BIT_RFCR_AAM (1<<29)
#define BIT_RFCR_AAB (1<<30)
#define BIT_RFCR_RFEN (1<<31)
#define REG_RFDR 19
#define REG_BRAR 20
#define BIT_BRAR_AUTOINC (1<<31)
#define REG_BRDR 21
#define REG_SRR 22
#define REG_MIBC 23
#define BIT_MIBC_WRN (1<<0)
#define BIT_MIBC_FRZ (1<<1)
#define REG_MIB0 24
#define REG_MIB1 25
#define REG_MIB2 26
#define REG_MIB3 27
#define REG_MIB4 28
#define REG_MIB5 29
#define REG_MIB6 30
#define REG_BMCR 32
#define BIT_BMCR_FDUP (1<<8)
#define BIT_BMCR_ANRST (1<<9)
#define BIT_BMCR_ISOL (1<<10)
#define BIT_BMCR_PDOWN (1<<11)
#define BIT_BMCR_ANEN (1<<12)
#define BIT_BMCR_SPEED (1<<13)
#define BIT_BMCR_LOOP (1<<14)
#define BIT_BMCR_RST (1<<15)
#define REG_BMSR 33
#define BIT_BMSR_JABBER (1<<1)
#define BIT_BMSR_LNK (1<<2)
#define BIT_BMSR_ANCAP (1<<3)
#define BIT_BMSR_RFAULT (1<<4)
#define BIT_BMSR_ANDONE (1<<5)
#define BIT_BMSR_PREAMBLE (1<<6)
#define BIT_BMSR_10HCAP (1<<11)
#define BIT_BMSR_10FCAP (1<<12)
#define BIT_BMSR_100HCAP (1<<13)
#define BIT_BMSR_100FCAP (1<<14)
#define BIT_BMSR_100T4CAP (1<<15)
#define REG_PHYIDR1 34
#define REG_PHYIDR2 35
#define BIT_PHYIDR2_OUILSB (0x3f<<10)
#define BIT_PHYIDR2_MODEL (0x3f<<4)
#define BIT_PHYIDR2_REV (0xf)
#define REG_ANAR 36
#define BIT_ANAR_PROTO (0x1f<<0)
#define BIT_ANAR_10 (1<<5)
#define BIT_ANAR_10_FD (1<<6)
#define BIT_ANAR_TX (1<<7)
#define BIT_ANAR_TXFD (1<<8)
#define BIT_ANAR_T4 (1<<9)
#define BIT_ANAR_PAUSE (1<<10)
#define BIT_ANAR_RF (1<<13)
#define BIT_ANAR_NP (1<<15)
#define REG_ANLPAR 37
#define BIT_ANLPAR_PROTO (0x1f<<0)
#define BIT_ANLPAR_10 (1<<5)
#define BIT_ANLPAR_10_FD (1<<6)
#define BIT_ANLPAR_TX (1<<7)
#define BIT_ANLPAR_TXFD (1<<8)
#define BIT_ANLPAR_T4 (1<<9)
#define BIT_ANLPAR_PAUSE (1<<10)
#define BIT_ANLPAR_RF (1<<13)
#define BIT_ANLPAR_ACK (1<<14)
#define BIT_ANLPAR_NP (1<<15)
#define REG_ANER 38
#define BIT_ANER_LP_AN_ENABLE (1<<0)
#define BIT_ANER_PAGE_RX (1<<1)
#define BIT_ANER_NP_ABLE (1<<2)
#define BIT_ANER_LP_NP_ABLE (1<<3)
#define BIT_ANER_PDF (1<<4)
#define REG_ANNPTR 39
#define REG_PHYSTS 48
#define BIT_PHYSTS_LNK (1<<0)
#define BIT_PHYSTS_SPD10 (1<<1)
#define BIT_PHYSTS_FDUP (1<<2)
#define BIT_PHYSTS_LOOP (1<<3)
#define BIT_PHYSTS_ANDONE (1<<4)
#define BIT_PHYSTS_JABBER (1<<5)
#define BIT_PHYSTS_RF (1<<6)
#define BIT_PHYSTS_MINT (1<<7)
#define BIT_PHYSTS_FC (1<<11)
#define BIT_PHYSTS_POL (1<<12)
#define BIT_PHYSTS_RXERR (1<<13)
#define REG_MICR 49
#define BIT_MICR_INTEN (1<<1)
#define REG_MISR 50
#define BIT_MISR_MSK_RHF (1<<9)
#define BIT_MISR_MSK_FHF (1<<10)
#define BIT_MISR_MSK_ANC (1<<11)
#define BIT_MISR_MSK_RF (1<<12)
#define BIT_MISR_MSK_JAB (1<<13)
#define BIT_MISR_MSK_LNK (1<<14)
#define BIT_MISR_MINT (1<<15)
#define REG_PGSEL 51
#define REG_FCSCR 52
#define REG_RECR 53
#define REG_PCSR 54
#define BIT_PCSR_NRZI (1<<2)
#define BIT_PCSR_FORCE_100 (1<<5)
#define BIT_PCSR_SDOPT (1<<8)
#define BIT_PCSR_SDFORCE (1<<9)
#define BIT_PCSR_TQM (1<<10)
#define BIT_PCSR_CLK (1<<11)
#define BIT_PCSR_4B5B (1<<12)
#define REG_PHYCR 57
#define BIT_PHYCR_PHYADDR (0x1f<<0)
#define BIT_PHYCR_PAUSE_STS (1<<7)
#define BIT_PHYCR_STRETCH (1<<8)
#define BIT_PHYCR_BIST (1<<9)
#define BIT_PHYCR_BIST_STAT (1<<10)
#define BIT_PHYCR_PSR15 (1<<11)
#define REG_TBTSCR 58
#define BIT_TBTSCR_JAB (1<<0)
#define BIT_TBTSCR_BEAT (1<<1)
#define BIT_TBTSCR_AUTOPOL (1<<3)
#define BIT_TBTSCR_POL (1<<4)
#define BIT_TBTSCR_FPOL (1<<5)
#define BIT_TBTSCR_FORCE_10 (1<<6)
#define BIT_TBTSCR_PULSE (1<<7)
#define BIT_TBTSCR_LOOP (1<<8)
#define REG_PMDCSR 64
#define REG_TSTDAT 65
#define REG_DSPCFG 66
#define REG_SDCFG 67
#define REG_PMATCH0 68
#define REG_PMATCH1 69
#define REG_PMATCH2 70
#define REG_PCOUNT0 71
#define REG_PCOUNT1 72
#define REG_SOPASS0 73
#define REG_SOPASS1 74
#define REG_SOPASS2 75
static void __print_intr(int d, int intr, const char *name,
const char *s1, const char *s2)
{
if ((d) & intr)
fprintf(stdout, " %s Interrupt: %s\n", name, s1);
else if (s2)
fprintf(stdout, " %s Interrupt: %s\n", name, s2);
}
#define PRINT_INTR(d, i, s1, s2) do { \
int intr = BIT_INTR_ ## i; \
const char *name = NAME_INTR_ ## i; \
__print_intr(d, intr, name, s1, s2); \
} while (0)
#define PRINT_INTRS(d, s1, s2) do { \
PRINT_INTR((d), RXOK, s1, s2); \
PRINT_INTR((d), RXDESC, s1, s2); \
PRINT_INTR((d), RXERR, s1, s2); \
PRINT_INTR((d), RXEARLY, s1, s2); \
PRINT_INTR((d), RXIDLE, s1, s2); \
PRINT_INTR((d), RXORN, s1, s2); \
PRINT_INTR((d), TXOK, s1, s2); \
PRINT_INTR((d), TXDESC, s1, s2); \
PRINT_INTR((d), TXERR, s1, s2); \
PRINT_INTR((d), TXIDLE, s1, s2); \
PRINT_INTR((d), TXURN, s1, s2); \
PRINT_INTR((d), MIB, s1, s2); \
PRINT_INTR((d), SWI, s1, s2); \
PRINT_INTR((d), PME, s1, s2); \
PRINT_INTR((d), PHY, s1, s2); \
PRINT_INTR((d), HIBERR, s1, s2); \
PRINT_INTR((d), RXSOVR, s1, s2); \
PRINT_INTR((d), RTABT, s1, s2); \
PRINT_INTR((d), RMABT, s1, s2); \
PRINT_INTR((d), SSERR, s1, s2); \
PRINT_INTR((d), DPERR, s1, s2); \
PRINT_INTR((d), RXRCMP, s1, s2); \
PRINT_INTR((d), TXRCMP, s1, s2); \
} while (0)
int
natsemi_dump_regs(struct ethtool_drvinfo *info maybe_unused,
struct ethtool_regs *regs)
{
u32 *data = (u32 *)regs->data;
u32 tmp;
fprintf(stdout, "Mac/BIU Registers\n");
fprintf(stdout, "-----------------\n");
/* command register */
fprintf(stdout,
"0x00: CR (Command): 0x%08x\n",
data[REG_CR]);
fprintf(stdout,
" Transmit %s\n"
" Receive %s\n",
data[REG_CR] & BIT_CR_TXE ? "Active" : "Idle",
data[REG_CR] & BIT_CR_RXE ? "Active" : "Idle");
if (data[REG_CR] & BIT_CR_RST) fprintf(stdout,
" Reset In Progress\n");
/* configuration register */
fprintf(stdout,
"0x04: CFG (Configuration): 0x%08x\n",
data[REG_CFG]);
fprintf(stdout,
" %s Endian\n"
" Boot ROM %s\n"
" Internal Phy %s\n"
" Phy Reset %s\n"
" External Phy %s\n"
" Default Auto-Negotiation %s, %s %s Mb %s Duplex\n"
" Phy Interrupt %sAuto-Cleared\n"
" Phy Configuration = 0x%02x\n"
" Auto-Negotiation %s\n"
" %s Polarity\n"
" %s Duplex\n"
" %d Mb/s\n"
" Link %s\n",
data[REG_CFG] & BIT_CFG_BEM ? "Big" : "Little",
data[REG_CFG] & BIT_CFG_BROM_DIS ? "Disabled" : "Enabled",
data[REG_CFG] & BIT_CFG_PHY_DIS ? "Disabled" : "Enabled",
data[REG_CFG] & BIT_CFG_PHY_RST ? "In Progress" : "Idle",
data[REG_CFG] & BIT_CFG_EXT_PHY ? "Enabled" : "Disabled",
data[REG_CFG] & BIT_CFG_ANEG_EN ? "Enabled" : "Disabled",
data[REG_CFG] & BIT_CFG_ANEG_EN ? "Advertise" : "Force",
data[REG_CFG] & BIT_CFG_ANEG_100 ?
(data[REG_CFG] & BIT_CFG_ANEG_EN ? "10/100" : "100")
: "10",
data[REG_CFG] & BIT_CFG_ANEG_FDUP ?
(data[REG_CFG] & BIT_CFG_ANEG_EN ? "Half/Full" : "Full")
: "Half",
data[REG_CFG] & BIT_CFG_PINT_ACEN ? "" : "Not ",
data[REG_CFG] & BIT_CFG_PHY_CFG >> 18,
data[REG_CFG] & BIT_CFG_ANEG_DN ? "Done" : "Not Done",
data[REG_CFG] & BIT_CFG_POL ? "Reversed" : "Normal",
data[REG_CFG] & BIT_CFG_FDUP ? "Full" : "Half",
data[REG_CFG] & BIT_CFG_SPEED100 ? 100 : 10,
data[REG_CFG] & BIT_CFG_LNKSTS ? "Up" : "Down");
/* EEPROM access register */
fprintf(stdout,
"0x08: MEAR (EEPROM Access): 0x%08x\n",
data[REG_MEAR]);
/* PCI test control register */
fprintf(stdout,
"0x0c: PTSCR (PCI Test Control): 0x%08x\n",
data[REG_PTSCR]);
fprintf(stdout,
" EEPROM Self Test %s\n"
" Rx Filter Self Test %s\n"
" Tx FIFO Self Test %s\n"
" Rx FIFO Self Test %s\n",
data[REG_PTSCR] & BIT_PTSCR_EEBIST_FAIL ? "Failed" : "Passed",
data[REG_PTSCR] & BIT_PTSCR_RBIST_RXFFAIL ? "Failed" : "Passed",
data[REG_PTSCR] & BIT_PTSCR_RBIST_TXFAIL ? "Failed" : "Passed",
data[REG_PTSCR] & BIT_PTSCR_RBIST_RXFAIL ? "Failed" : "Passed");
if (data[REG_PTSCR] & BIT_PTSCR_EELOAD_EN) fprintf(stdout,
" EEPROM Reload In Progress\n");
/* Interrupt status register */
fprintf(stdout,
"0x10: ISR (Interrupt Status): 0x%08x\n",
data[REG_ISR]);
if (data[REG_ISR])
PRINT_INTRS(data[REG_ISR], "Active", (char *)NULL);
else
fprintf(stdout, " No Interrupts Active\n");
/* Interrupt mask register */
fprintf(stdout,
"0x14: IMR (Interrupt Mask): 0x%08x\n",
data[REG_IMR]);
PRINT_INTRS(data[REG_IMR], "Enabled", "Masked");
/* Interrupt enable register */
fprintf(stdout,
"0x18: IER (Interrupt Enable): 0x%08x\n",
data[REG_IER]);
fprintf(stdout,
" Interrupts %s\n",
data[REG_IER] & BIT_IER_IE ? "Enabled" : "Disabled");
/* Tx descriptor pointer register */
fprintf(stdout,
"0x20: TXDP (Tx Descriptor Pointer): 0x%08x\n",
data[REG_TXDP]);
/* Tx configuration register */
fprintf(stdout,
"0x24: TXCFG (Tx Config): 0x%08x\n",
data[REG_TXCFG]);
tmp = (data[REG_TXCFG] & BIT_TXCFG_MXDMA)>>20;
fprintf(stdout,
" Drain Threshold = %d bytes (%d)\n"
" Fill Threshold = %d bytes (%d)\n"
" Max DMA Burst per Tx = %d bytes\n"
" Automatic Tx Padding %s\n"
" Mac Loopback %s\n"
" Heartbeat Ignore %s\n"
" Carrier Sense Ignore %s\n",
(data[REG_TXCFG] & BIT_TXCFG_DRTH) * 32,
data[REG_TXCFG] & BIT_TXCFG_DRTH,
((data[REG_TXCFG] & BIT_TXCFG_FLTH)>>8) * 32,
data[REG_TXCFG] & BIT_TXCFG_FLTH,
tmp ? (1<<(tmp-1))*4 : 512,
data[REG_TXCFG] & BIT_TXCFG_ATP ? "Enabled" : "Disabled",
data[REG_TXCFG] & BIT_TXCFG_MLB ? "Enabled" : "Disabled",
data[REG_TXCFG] & BIT_TXCFG_HBI ? "Enabled" : "Disabled",
data[REG_TXCFG] & BIT_TXCFG_CSI ? "Enabled" : "Disabled");
/* Rx descriptor pointer register */
fprintf(stdout,
"0x30: RXDP (Rx Descriptor Pointer): 0x%08x\n",
data[REG_RXDP]);
/* Rx configuration register */
fprintf(stdout,
"0x34: RXCFG (Rx Config): 0x%08x\n",
data[REG_RXCFG]);
tmp = (data[REG_RXCFG] & BIT_RXCFG_MXDMA)>>20;
fprintf(stdout,
" Drain Threshold = %d bytes (%d)\n"
" Max DMA Burst per Rx = %d bytes\n"
" Long Packets %s\n"
" Tx Packets %s\n"
" Runt Packets %s\n"
" Error Packets %s\n",
((data[REG_RXCFG] & BIT_RXCFG_DRTH) >> 1) * 8,
(data[REG_RXCFG] & BIT_RXCFG_DRTH) >> 1,
tmp ? (1<<(tmp-1))*4 : 512,
data[REG_RXCFG] & BIT_RXCFG_ALP ? "Accepted" : "Rejected",
data[REG_RXCFG] & BIT_RXCFG_ATX ? "Accepted" : "Rejected",
data[REG_RXCFG] & BIT_RXCFG_ARP ? "Accepted" : "Rejected",
data[REG_RXCFG] & BIT_RXCFG_AEP ? "Accepted" : "Rejected");
/* CLKRUN control/status register */
fprintf(stdout,
"0x3c: CCSR (CLKRUN Control/Status): 0x%08x\n",
data[REG_CCSR]);
fprintf(stdout,
" CLKRUNN %s\n"
" Power Management %s\n",
data[REG_CCSR] & BIT_CCSR_CLKRUN_EN ? "Enabled" : "Disabled",
data[REG_CCSR] & BIT_CCSR_PMEEN ? "Enabled" : "Disabled");
if (data[REG_CCSR] & BIT_CCSR_PMESTS) fprintf(stdout,
" Power Management Event Pending\n");
/* WoL control/status register */
fprintf(stdout,
"0x40: WCSR (Wake-on-LAN Control/Status): 0x%08x\n",
data[REG_WCSR]);
if (data[REG_WCSR] & BIT_WCSR_WKPHY) fprintf(stdout,
" Wake on Phy Interrupt Enabled\n");
if (data[REG_WCSR] & BIT_WCSR_WKUCP) fprintf(stdout,
" Wake on Unicast Packet Enabled\n");
if (data[REG_WCSR] & BIT_WCSR_WKMCP) fprintf(stdout,
" Wake on Multicast Packet Enabled\n");
if (data[REG_WCSR] & BIT_WCSR_WKBCP) fprintf(stdout,
" Wake on Broadcast Packet Enabled\n");
if (data[REG_WCSR] & BIT_WCSR_WKARP) fprintf(stdout,
" Wake on Arp Enabled\n");
if (data[REG_WCSR] & BIT_WCSR_WKPAT0) fprintf(stdout,
" Wake on Pattern 0 Match Enabled\n");
if (data[REG_WCSR] & BIT_WCSR_WKPAT1) fprintf(stdout,
" Wake on Pattern 1 Match Enabled\n");
if (data[REG_WCSR] & BIT_WCSR_WKPAT2) fprintf(stdout,
" Wake on Pattern 2 Match Enabled\n");
if (data[REG_WCSR] & BIT_WCSR_WKPAT3) fprintf(stdout,
" Wake on Pattern 3 Match Enabled\n");
if (data[REG_WCSR] & BIT_WCSR_WKMAG) fprintf(stdout,
" Wake on Magic Packet Enabled\n");
if (data[REG_WCSR] & BIT_WCSR_MPSOE) fprintf(stdout,
" Magic Packet SecureOn Enabled\n");
if (data[REG_WCSR] & BIT_WCSR_SOHACK) fprintf(stdout,
" SecureOn Hack Detected\n");
if (data[REG_WCSR] & BIT_WCSR_PHYINT) fprintf(stdout,
" Phy Interrupt Received\n");
if (data[REG_WCSR] & BIT_WCSR_UCASTR) fprintf(stdout,
" Unicast Packet Received\n");
if (data[REG_WCSR] & BIT_WCSR_MCASTR) fprintf(stdout,
" Multicast Packet Received\n");
if (data[REG_WCSR] & BIT_WCSR_BCASTR) fprintf(stdout,
" Broadcast Packet Received\n");
if (data[REG_WCSR] & BIT_WCSR_ARPR) fprintf(stdout,
" Arp Received\n");
if (data[REG_WCSR] & BIT_WCSR_PATM0) fprintf(stdout,
" Pattern 0 Received\n");
if (data[REG_WCSR] & BIT_WCSR_PATM1) fprintf(stdout,
" Pattern 1 Received\n");
if (data[REG_WCSR] & BIT_WCSR_PATM2) fprintf(stdout,
" Pattern 2 Received\n");
if (data[REG_WCSR] & BIT_WCSR_PATM3) fprintf(stdout,
" Pattern 3 Received\n");
if (data[REG_WCSR] & BIT_WCSR_MPR) fprintf(stdout,
" Magic Packet Received\n");
/* Pause control/status register */
fprintf(stdout,
"0x44: PCR (Pause Control/Status): 0x%08x\n",
data[REG_PCR]);
fprintf(stdout,
" Pause Counter = %d\n"
" Pause %sNegotiated\n"
" Pause on DA %s\n"
" Pause on Mulitcast %s\n"
" Pause %s\n",
data[REG_PCR] & BIT_PCR_PAUSE_CNT,
data[REG_PCR] & BIT_PCR_PSNEG ? "" : "Not ",
data[REG_PCR] & BIT_PCR_PS_DA ? "Enabled" : "Disabled",
data[REG_PCR] & BIT_PCR_PSMCAST ? "Enabled" : "Disabled",
data[REG_PCR] & BIT_PCR_PSEN ? "Enabled" : "Disabled");
if (data[REG_PCR] & BIT_PCR_PS_RCVD) fprintf(stdout,
" PS_RCVD: Pause Frame Received\n");
/* Rx Filter Control */
fprintf(stdout,
"0x48: RFCR (Rx Filter Control): 0x%08x\n",
data[REG_RFCR]);
fprintf(stdout,
" Unicast Hash %s\n"
" Multicast Hash %s\n"
" Arp %s\n"
" Pattern 0 Match %s\n"
" Pattern 1 Match %s\n"
" Pattern 2 Match %s\n"
" Pattern 3 Match %s\n"
" Perfect Match %s\n"
" All Unicast %s\n"
" All Multicast %s\n"
" All Broadcast %s\n"
" Rx Filter %s\n",
data[REG_RFCR] & BIT_RFCR_UHEN ? "Enabled" : "Disabled",
data[REG_RFCR] & BIT_RFCR_MHEN ? "Enabled" : "Disabled",
data[REG_RFCR] & BIT_RFCR_AARP ? "Accepted" : "Rejected",
data[REG_RFCR] & BIT_RFCR_APAT0 ? "Accepted" : "Rejected",
data[REG_RFCR] & BIT_RFCR_APAT1 ? "Accepted" : "Rejected",
data[REG_RFCR] & BIT_RFCR_APAT2 ? "Accepted" : "Rejected",
data[REG_RFCR] & BIT_RFCR_APAT3 ? "Accepted" : "Rejected",
data[REG_RFCR] & BIT_RFCR_APM ? "Accepted" : "Rejected",
data[REG_RFCR] & BIT_RFCR_AAU ? "Accepted" : "Rejected",
data[REG_RFCR] & BIT_RFCR_AAM ? "Accepted" : "Rejected",
data[REG_RFCR] & BIT_RFCR_AAB ? "Accepted" : "Rejected",
data[REG_RFCR] & BIT_RFCR_RFEN ? "Enabled" : "Disabled");
/* Rx filter data register */
fprintf(stdout,
"0x4c: RFDR (Rx Filter Data): 0x%08x\n",
data[REG_RFDR]);
if (regs->version >= 1) fprintf(stdout,
" PMATCH 1-0 = 0x%08x\n"
" PMATCH 3-2 = 0x%08x\n"
" PMATCH 5-4 = 0x%08x\n"
" PCOUNT 1-0 = 0x%08x\n"
" PCOUNT 3-2 = 0x%08x\n"
" SOPASS 1-0 = 0x%08x\n"
" SOPASS 3-2 = 0x%08x\n"
" SOPASS 5-4 = 0x%08x\n",
data[REG_PMATCH0], data[REG_PMATCH1], data[REG_PMATCH2],
data[REG_PCOUNT0], data[REG_PCOUNT1],
data[REG_SOPASS0], data[REG_SOPASS1], data[REG_SOPASS2]);
/* Boot ROM address register */
fprintf(stdout,
"0x50: BRAR (Boot ROM Address): 0x%08x\n",
data[REG_BRAR]);
if (data[REG_BRAR] & BIT_BRAR_AUTOINC) fprintf(stdout,
" Automatically Increment Address\n");
/* Boot ROM data register */
fprintf(stdout,
"0x54: BRDR (Boot ROM Data): 0x%08x\n",
data[REG_BRDR]);
/* Silicon revison register */
fprintf(stdout,
"0x58: SRR (Silicon Revision): 0x%08x\n",
data[REG_SRR]);
/* Management information base control register */
fprintf(stdout,
"0x5c: MIBC (Mgmt Info Base Control): 0x%08x\n",
data[REG_MIBC]);
if (data[REG_MIBC] & BIT_MIBC_WRN) fprintf(stdout,
" Counter Overflow Warning\n");
if (data[REG_MIBC] & BIT_MIBC_FRZ) fprintf(stdout,
" Counters Frozen\n");
/* MIB registers */
fprintf(stdout,
"0x60: MIB[0] (Rx Errored Packets): 0x%04x\n",
data[REG_MIB0]);
fprintf(stdout, " Value = %d\n", data[REG_MIB0]);
fprintf(stdout,
"0x64: MIB[1] (Rx Frame Sequence Errors): 0x%02x\n",
data[REG_MIB1]);
fprintf(stdout, " Value = %d\n", data[REG_MIB1]);
fprintf(stdout,
"0x68: MIB[2] (Rx Missed Packets): 0x%02x\n",
data[REG_MIB2]);
fprintf(stdout, " Value = %d\n", data[REG_MIB2]);
fprintf(stdout,
"0x6c: MIB[3] (Rx Alignment Errors): 0x%02x\n",
data[REG_MIB3]);
fprintf(stdout, " Value = %d\n", data[REG_MIB3]);
fprintf(stdout,
"0x70: MIB[4] (Rx Symbol Errors): 0x%02x\n",
data[REG_MIB4]);
fprintf(stdout, " Value = %d\n", data[REG_MIB4]);
fprintf(stdout,
"0x74: MIB[5] (Rx Long Frame Errors): 0x%02x\n",
data[REG_MIB5]);
fprintf(stdout, " Value = %d\n", data[REG_MIB5]);
fprintf(stdout,
"0x78: MIB[6] (Tx Heartbeat Errors): 0x%02x\n",
data[REG_MIB6]);
fprintf(stdout, " Value = %d\n", data[REG_MIB6]);
fprintf(stdout, "\n");
fprintf(stdout, "Internal Phy Registers\n");
fprintf(stdout, "----------------------\n");
/* Basic mode control register */
fprintf(stdout,
"0x80: BMCR (Basic Mode Control): 0x%04x\n",
data[REG_BMCR]);
fprintf(stdout,
" %s Duplex\n"
" Port is Powered %s\n"
" Auto-Negotiation %s\n"
" %d Mb/s\n",
data[REG_BMCR] & BIT_BMCR_FDUP ? "Full" : "Half",
data[REG_BMCR] & BIT_BMCR_PDOWN ? "Down" : "Up",
data[REG_BMCR] & BIT_BMCR_ANEN ? "Enabled" : "Disabled",
data[REG_BMCR] & BIT_BMCR_SPEED ? 100 : 10);
if (data[REG_BMCR] & BIT_BMCR_ANRST) fprintf(stdout,
" Auto-Negotiation Restarting\n");
if (data[REG_BMCR] & BIT_BMCR_ISOL) fprintf(stdout,
" Port Isolated\n");
if (data[REG_BMCR] & BIT_BMCR_LOOP) fprintf(stdout,
" Loopback Enabled\n");
if (data[REG_BMCR] & BIT_BMCR_RST) fprintf(stdout,
" Reset In Progress\n");
/* Basic mode status register */
fprintf(stdout,
"0x84: BMSR (Basic Mode Status): 0x%04x\n",
data[REG_BMSR]);
fprintf(stdout,
" Link %s\n"
" %sCapable of Auto-Negotiation\n"
" Auto-Negotiation %sComplete\n"
" %sCapable of Preamble Suppression\n"
" %sCapable of 10Base-T Half Duplex\n"
" %sCapable of 10Base-T Full Duplex\n"
" %sCapable of 100Base-TX Half Duplex\n"
" %sCapable of 100Base-TX Full Duplex\n"
" %sCapable of 100Base-T4\n",
data[REG_BMSR] & BIT_BMSR_LNK ? "Up" : "Down",
data[REG_BMSR] & BIT_BMSR_ANCAP ? "" : "Not ",
data[REG_BMSR] & BIT_BMSR_ANDONE ? "" : "Not ",
data[REG_BMSR] & BIT_BMSR_PREAMBLE ? "" : "Not ",
data[REG_BMSR] & BIT_BMSR_10HCAP ? "" : "Not ",
data[REG_BMSR] & BIT_BMSR_10FCAP ? "" : "Not ",
data[REG_BMSR] & BIT_BMSR_100HCAP ? "" : "Not ",
data[REG_BMSR] & BIT_BMSR_100FCAP ? "" : "Not ",
data[REG_BMSR] & BIT_BMSR_100T4CAP ? "" : "Not ");
if (data[REG_BMSR] & BIT_BMSR_JABBER) fprintf(stdout,
" Jabber Condition Detected\n");
if (data[REG_BMSR] & BIT_BMSR_RFAULT) fprintf(stdout,
" Remote Fault Detected\n");
/* PHY identification registers */
fprintf(stdout,
"0x88: PHYIDR1 (PHY ID #1): 0x%04x\n",
data[REG_PHYIDR1]);
fprintf(stdout,
"0x8c: PHYIDR2 (PHY ID #2): 0x%04x\n",
data[REG_PHYIDR2]);
fprintf(stdout,
" OUI = 0x%06x\n"
" Model = 0x%02x (%d)\n"
" Revision = 0x%01x (%d)\n",
(data[REG_PHYIDR1] << 6) | (data[REG_PHYIDR2] >> 10),
(data[REG_PHYIDR2] & BIT_PHYIDR2_MODEL) >> 4 & 0x3f,
(data[REG_PHYIDR2] & BIT_PHYIDR2_MODEL) >> 4 & 0x3f,
data[REG_PHYIDR2] & BIT_PHYIDR2_REV,
data[REG_PHYIDR2] & BIT_PHYIDR2_REV);
/* autonegotiation advertising register */
fprintf(stdout,
"0x90: ANAR (Autoneg Advertising): 0x%04x\n",
data[REG_ANAR]);
fprintf(stdout,
" Protocol Selector = 0x%02x (%d)\n",
data[REG_ANAR] & BIT_ANAR_PROTO,
data[REG_ANAR] & BIT_ANAR_PROTO);
if (data[REG_ANAR] & BIT_ANAR_10) fprintf(stdout,
" Advertising 10Base-T Half Duplex\n");
if (data[REG_ANAR] & BIT_ANAR_10_FD) fprintf(stdout,
" Advertising 10Base-T Full Duplex\n");
if (data[REG_ANAR] & BIT_ANAR_TX) fprintf(stdout,
" Advertising 100Base-TX Half Duplex\n");
if (data[REG_ANAR] & BIT_ANAR_TXFD) fprintf(stdout,
" Advertising 100Base-TX Full Duplex\n");
if (data[REG_ANAR] & BIT_ANAR_T4) fprintf(stdout,
" Advertising 100Base-T4\n");
if (data[REG_ANAR] & BIT_ANAR_PAUSE) fprintf(stdout,
" Advertising Pause\n");
if (data[REG_ANAR] & BIT_ANAR_RF) fprintf(stdout,
" Indicating Remote Fault\n");
if (data[REG_ANAR] & BIT_ANAR_NP) fprintf(stdout,
" Next Page Desired\n");
/* Autonegotiation link partner ability register */
fprintf(stdout,
"0x94: ANLPAR (Autoneg Partner): 0x%04x\n",
data[REG_ANLPAR]);
fprintf(stdout,
" Protocol Selector = 0x%02x (%d)\n",
data[REG_ANLPAR] & BIT_ANLPAR_PROTO,
data[REG_ANLPAR] & BIT_ANLPAR_PROTO);
if (data[REG_ANLPAR] & BIT_ANLPAR_10) fprintf(stdout,
" Supports 10Base-T Half Duplex\n");
if (data[REG_ANLPAR] & BIT_ANLPAR_10_FD) fprintf(stdout,
" Supports 10Base-T Full Duplex\n");
if (data[REG_ANLPAR] & BIT_ANLPAR_TX) fprintf(stdout,
" Supports 100Base-TX Half Duplex\n");
if (data[REG_ANLPAR] & BIT_ANLPAR_TXFD) fprintf(stdout,
" Supports 100Base-TX Full Duplex\n");
if (data[REG_ANLPAR] & BIT_ANLPAR_T4) fprintf(stdout,
" Supports 100Base-T4\n");
if (data[REG_ANLPAR] & BIT_ANLPAR_PAUSE) fprintf(stdout,
" Supports Pause\n");
if (data[REG_ANLPAR] & BIT_ANLPAR_RF) fprintf(stdout,
" Indicates Remote Fault\n");
if (data[REG_ANLPAR] & BIT_ANLPAR_ACK) fprintf(stdout,
" Indicates Acknowledgement\n");
if (data[REG_ANLPAR] & BIT_ANLPAR_NP) fprintf(stdout,
" Next Page Desired\n");
/* Autonegotiation expansion register */
fprintf(stdout,
"0x98: ANER (Autoneg Expansion): 0x%04x\n",
data[REG_ANER]);
fprintf(stdout,
" Link Partner Can %sAuto-Negotiate\n"
" Link Code Word %sReceived\n"
" Next Page %sSupported\n"
" Link Partner Next Page %sSupported\n",
data[REG_ANER] & BIT_ANER_LP_AN_ENABLE ? "" : "Not ",
data[REG_ANER] & BIT_ANER_PAGE_RX ? "" : "Not ",
data[REG_ANER] & BIT_ANER_NP_ABLE ? "" : "Not ",
data[REG_ANER] & BIT_ANER_LP_NP_ABLE ? "" : "Not ");
if (data[REG_ANER] & BIT_ANER_PDF) fprintf(stdout,
" Parallel Detection Fault\n");
/* Autonegotiation next-page tx register */
fprintf(stdout,
"0x9c: ANNPTR (Autoneg Next Page Tx): 0x%04x\n",
data[REG_ANNPTR]);
/* Phy status register */
fprintf(stdout,
"0xc0: PHYSTS (Phy Status): 0x%04x\n",
data[REG_PHYSTS]);
fprintf(stdout,
" Link %s\n"
" %d Mb/s\n"
" %s Duplex\n"
" Auto-Negotiation %sComplete\n"
" %s Polarity\n",
data[REG_PHYSTS] & BIT_PHYSTS_LNK ? "Up" : "Down",
data[REG_PHYSTS] & BIT_PHYSTS_SPD10 ? 10 : 100,
data[REG_PHYSTS] & BIT_PHYSTS_FDUP ? "Full" : "Half",
data[REG_PHYSTS] & BIT_PHYSTS_ANDONE ? "" : "Not ",
data[REG_PHYSTS] & BIT_PHYSTS_POL ? "Reverse" : "Normal");
if (data[REG_PHYSTS] & BIT_PHYSTS_LOOP) fprintf(stdout,
" Loopback Enabled\n");
if (data[REG_PHYSTS] & BIT_PHYSTS_JABBER) fprintf(stdout,
" Jabber Condition Detected\n");
if (data[REG_PHYSTS] & BIT_PHYSTS_RF) fprintf(stdout,
" Remote Fault Detected\n");
if (data[REG_PHYSTS] & BIT_PHYSTS_MINT) fprintf(stdout,
" MII Interrupt Detected\n");
if (data[REG_PHYSTS] & BIT_PHYSTS_FC) fprintf(stdout,
" False Carrier Detected\n");
if (data[REG_PHYSTS] & BIT_PHYSTS_RXERR) fprintf(stdout,
" Rx Error Detected\n");
fprintf(stdout,
"0xc4: MICR (MII Interrupt Control): 0x%04x\n",
data[REG_MICR]);
fprintf(stdout,
" MII Interrupts %s\n",
data[REG_MICR] & BIT_MICR_INTEN ? "Enabled" : "Disabled");
fprintf(stdout,
"0xc8: MISR (MII Interrupt Status): 0x%04x\n",
data[REG_MISR]);
fprintf(stdout,
" Rx Error Counter Half-Full Interrupt %s\n"
" False Carrier Counter Half-Full Interrupt %s\n"
" Auto-Negotiation Complete Interrupt %s\n"
" Remote Fault Interrupt %s\n"
" Jabber Interrupt %s\n"
" Link Change Interrupt %s\n",
data[REG_MISR] & BIT_MISR_MSK_RHF ? "Masked" : "Enabled",
data[REG_MISR] & BIT_MISR_MSK_FHF ? "Masked" : "Enabled",
data[REG_MISR] & BIT_MISR_MSK_ANC ? "Masked" : "Enabled",
data[REG_MISR] & BIT_MISR_MSK_RF ? "Masked" : "Enabled",
data[REG_MISR] & BIT_MISR_MSK_JAB ? "Masked" : "Enabled",
data[REG_MISR] & BIT_MISR_MSK_LNK ? "Masked" : "Enabled");
if (data[REG_MISR] & BIT_MISR_MINT) fprintf(stdout,
" MII Interrupt Pending\n");
/* Page select register (from section of spec on 'suggested values') */
fprintf(stdout,
"0xcc: PGSEL (Phy Register Page Select): 0x%04x\n",
data[REG_PGSEL]);
/* counters */
fprintf(stdout,
"0xd0: FCSCR (False Carrier Counter): 0x%04x\n",
data[REG_FCSCR]);
fprintf(stdout,
" Value = %d\n", data[REG_FCSCR] & 0xff);
fprintf(stdout,
"0xd4: RECR (Rx Error Counter): 0x%04x\n",
data[REG_RECR]);
fprintf(stdout,
" Value = %d\n", data[REG_RECR] & 0xff);
/* 100 Mbit configuration register */
fprintf(stdout,
"0xd8: PCSR (100Mb/s PCS Config/Status): 0x%04x\n",
data[REG_PCSR]);
fprintf(stdout,
" NRZI Bypass %s\n"
" %s Signal Detect Algorithm\n"
" %s Signal Detect Operation\n"
" True Quiet Mode %s\n"
" Rx Clock is %s\n"
" 4B/5B Operation %s\n",
data[REG_PCSR] & BIT_PCSR_NRZI ? "Enabled" : "Disabled",
data[REG_PCSR] & BIT_PCSR_SDOPT ? "Enhanced" : "Reduced",
data[REG_PCSR] & BIT_PCSR_SDFORCE ? "Forced" : "Normal",
data[REG_PCSR] & BIT_PCSR_TQM ? "Enabled" : "Disabled",
data[REG_PCSR] & BIT_PCSR_CLK ?
"Free-Running" : "Phase-Adjusted",
data[REG_PCSR] & BIT_PCSR_4B5B ? "Bypassed" : "Normal");
if (data[REG_PCSR] & BIT_PCSR_FORCE_100) fprintf(stdout,
" Forced 100 Mb/s Good Link\n");
/* Phy control register */
fprintf(stdout,
"0xe4: PHYCR (Phy Control): 0x%04x\n",
data[REG_PHYCR]);
fprintf(stdout,
" Phy Address = 0x%x (%d)\n"
" %sPause Compatible with Link Partner\n"
" LED Stretching %s\n"
" Phy Self Test %s\n"
" Self Test Sequence = PSR%d\n",
data[REG_PHYCR] & BIT_PHYCR_PHYADDR,
data[REG_PHYCR] & BIT_PHYCR_PHYADDR,
data[REG_PHYCR] & BIT_PHYCR_PAUSE_STS ? "" : "Not ",
data[REG_PHYCR] & BIT_PHYCR_STRETCH ? "Bypassed" : "Enabled",
data[REG_PHYCR] & BIT_PHYCR_BIST ? "In Progress" :
data[REG_PHYCR] & BIT_PHYCR_BIST_STAT ?
"Passed" : "Failed or Not Run",
data[REG_PHYCR] & BIT_PHYCR_PSR15 ? 15 : 9);
/* 10 Mbit control and status register */
fprintf(stdout,
"0xe8: TBTSCR (10Base-T Status/Control): 0x%04x\n",
data[REG_TBTSCR]);
fprintf(stdout,
" Jabber %s\n"
" Heartbeat %s\n"
" Polarity Auto-Sense/Correct %s\n"
" %s Polarity %s\n"
" Normal Link Pulse %s\n"
" 10 Mb/s Loopback %s\n",
data[REG_TBTSCR] & BIT_TBTSCR_JAB ? "Disabled" : "Enabled",
data[REG_TBTSCR] & BIT_TBTSCR_BEAT ? "Disabled" : "Enabled",
data[REG_TBTSCR] & BIT_TBTSCR_AUTOPOL ? "Disabled" : "Enabled",
data[REG_TBTSCR] & BIT_TBTSCR_AUTOPOL ?
data[REG_TBTSCR]&BIT_TBTSCR_FPOL ? "Reverse":"Normal" :
data[REG_TBTSCR]&BIT_TBTSCR_POL ? "Reverse":"Normal",
data[REG_TBTSCR] & BIT_TBTSCR_AUTOPOL ? "Forced" : "Detected",
data[REG_TBTSCR] & BIT_TBTSCR_PULSE ? "Disabled" : "Enabled",
data[REG_TBTSCR] & BIT_TBTSCR_LOOP ? "Enabled" : "Disabled");
if (data[REG_TBTSCR] & BIT_TBTSCR_FORCE_10) fprintf(stdout,
" Forced 10 Mb/s Good Link\n");
/* the spec says to set these */
fprintf(stdout, "\n");
fprintf(stdout, "'Magic' Phy Registers\n");
fprintf(stdout, "---------------------\n");
fprintf(stdout,
"0xe4: PMDCSR: 0x%04x\n",
data[REG_PMDCSR]);
fprintf(stdout,
"0xf4: DSPCFG: 0x%04x\n",
data[REG_DSPCFG]);
fprintf(stdout,
"0xf8: SDCFG: 0x%04x\n",
data[REG_SDCFG]);
fprintf(stdout,
"0xfc: TSTDAT: 0x%04x\n",
data[REG_TSTDAT]);
return 0;
}
int
natsemi_dump_eeprom(struct ethtool_drvinfo *info maybe_unused,
struct ethtool_eeprom *ee)
{
int i;
u16 *eebuf = (u16 *)ee->data;
if (ee->magic != NATSEMI_MAGIC) {
fprintf(stderr, "Magic number 0x%08x does not match 0x%08x\n",
ee->magic, NATSEMI_MAGIC);
return -1;
}
fprintf(stdout, "Address\tData\n");
fprintf(stdout, "-------\t------\n");
for (i = 0; i < ee->len/2; i++) {
fprintf(stdout, "0x%02x \t0x%04x\n", i + ee->offset, eebuf[i]);
}
return 0;
}